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Non-Mendelian Genetics

Non-Mendelian Genetics. phenotype: purple. phenotype: white. phenotype: purple. Mendelian Genetics: Dominant & Recessive Review. One allele is DOMINANT over the other and the dominant allele will totally mask the recessive allele. genotype: PP. genotype: pp. genotype: Pp.

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Non-Mendelian Genetics

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  1. Non-Mendelian Genetics

  2. phenotype: purple phenotype: white phenotype: purple Mendelian Genetics: Dominant & Recessive Review • One allele is DOMINANT over the other and the dominant allele will totally mask the recessive allele genotype: PP genotype: pp genotype: Pp

  3. Review Problem: Dominant & Recessive • In pea plants, purple flowers (P) are dominant over white flowers (p). Show the cross between two heterozygous plants. GENOTYPES: - % - ratio PHENOTYPES: - % - ratio

  4. It’s not always Dominant/Recessive! Non-Mendelian Inheritance Patterns • Incomplete Dominance • Codominance • Multiple Alleles • Polygenic Traits • Sex-Linked Traits

  5. RR = red rr = white Rr = pink Incomplete Dominance • a new phenotype appears in the heterozygouscondition as a BLEND of the dominant and recessivephenotypes. Ex - Dominant Red (RR) + Recessive White (rr) = Hybrid Pink (Rr)

  6. Problem: Incomplete Dominance • Show the cross between a red and a white flower. GENOTYPES: - % - ratio PHENOTYPES: - % - ratio

  7. Problem: Incomplete Dominance • Show the cross between a pink and a white flower. GENOTYPES: - % - ratio PHENOTYPES: - % - ratio

  8. NS = some of each SS = sickle cells NN = normal cells Codominance • in the heterozygous condition, both alleles are expressed equally with NO blending! Represented by using two DIFFERENT capital letters. • Example - Sickle Cell Anemia: All Normal Cells (NN) + All sickled cells (SS) = half normal/half sickle carrier (NS) sick

  9. Codominance Example: Checkered Chickens • BB = all black feathers • WW = all white feathers • BW = both black & white feathers (speckled) • Notice – NO GRAY! NO BLEND! Each feather is either black or white

  10. Codominance Example: Rhodedendron • R = allele for red flowers • W = allele for white flowers • Cross a homozygous red flower with a homozygous white flower.

  11. Codominance Example: Roan cattle • cattle can be red (RR – all red hairs) white (WW – all white hairs) roan (RW – red and white hairs together)

  12. Problem: Codominance in Appaloosa Horses • Gray horses (GG) are codominant to white horses (WW). The heterozygous horse (GW) is an Appaloosa (a white horse with gray spots). • Cross a white horse with an appaloosa horse. Give the genotype and phenotype ratio and percent.

  13. Problem: Codominance in Sickle Cell • Show the cross between an individual with sickle-cell anemia and another who is a carrier but not sick. GENOTYPES: - % - ratio PHENOTYPES: - % - ratio

  14. Multiple Alleles • Sometimes there are more than twoalleles present in the gene pool for a gene. Ex – blood type consists of two dominant and one recessive allele in humans Allele A (IA) and B (IB) are dominant over Allele O (i). (NOTE: You still only get TWO alleles!!! One from mom and one from dad)

  15. Multiple Alleles: Rabbit Fur Colors • Fur colors (determined by 4 alleles):full color (C), chinchilla (cch), Himalayan (ch), albino (c)

  16. Multiple Alleles: Blood Types (A, B, AB, O) • Rules for Blood Types: (geno = pheno) A and B are co-dominant (Both show) IAIA = type A IBIB = type B IAIB = type AB A and B are both dominant over O (Regular dom/rec) IAi = type A IBi = type B ii = type O

  17. Multiple Alleles: Blood Types (A, B, AB, O)

  18. Problem: Multiple Alleles • Show the cross between a mother who has type O blood and a father who has type AB blood. GENOTYPES: - list PHENOTYPES: - list

  19. Problem: Multiple Alleles • Show the cross between a mother who is heterozygous for type B blood and a father who is heterozygous for type A blood. GENOTYPES: • list PHENOTYPES: • list

  20. Sex-Linked Traits • Non-gender related genes that are attached to the X chromosome, but not found on the Y chromosome. (Women have XX so they get two of these genes. Men have XY chromosomes so they only get one copy.) • examples: red-green colorblindness, hemophilia, muscular dystrophy

  21. Sex-Linked Traits • These disorders are more common in boys since girls have a “back up” X. • In males, there is no back up to cover a recessive gene. If they get an X with the disorder, they use it. Girls must inherit defective Xs from both parents to have the disorder, otherwise their “back up” will kick in.

  22. Sex-Linked Traits A: 29, B: 45, C: --, D: 26  Normal vision A: 70, B: --, C: 5, D: --  Red-green color blind A: 70, B: --, C: 5, D: 6  Red color blind A: 70, B: --, C: 5, D: 2  Green color blind

  23. Problem: Sex Linked • Show the cross between a mother whose father was colorblind and a normal vision man GENOTYPES: • Male % • Female % PHENOTYPES: • Male % • Female %

  24. Problem: Sex Linked • Show a cross between a carrier mother and a male with hemophilia GENOTYPES: • Male % • Female % PHENOTYPES: • Male % • Female %

  25. Polygenic Traits • traits produced by more than one pair of genes; results in a variety of phenotypes • example: skin color, eye color, height (No punnett square)

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